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/*!
* \file board.c
*
* \brief Target board general functions implementation
*
* \copyright Revised BSD License, see section \ref LICENSE.
*
* \code
* ______ _
* / _____) _ | |
* ( (____ _____ ____ _| |_ _____ ____| |__
* \____ \| ___ | (_ _) ___ |/ ___) _ \
* _____) ) ____| | | || |_| ____( (___| | | |
* (______/|_____)_|_|_| \__)_____)\____)_| |_|
* (C)2013-2017 Semtech
*
* \endcode
*
* \author Miguel Luis ( Semtech )
*
* \author Gregory Cristian ( Semtech )
*
* \author Andreas Pella ( IMST GmbH )
*/
#include "stm32l1xx.h"
#include "utilities.h"
#include "gpio.h"
#include "adc.h"
#include "spi.h"
#include "i2c.h"
#include "uart.h"
#include "timer.h"
#include "sysIrqHandlers.h"
#include "board-config.h"
#include "lpm-board.h"
#include "rtc-board.h"
#include "sx1272-board.h"
#include "board.h"
/*!
* Unique Devices IDs register set ( STM32L1xxx )
*/
#define ID1 ( 0x1FF80050 )
#define ID2 ( 0x1FF80054 )
#define ID3 ( 0x1FF80064 )
/*!
* LED GPIO pins objects
*/
#if ( USE_POTENTIOMETER == 0 )
Gpio_t Led1;
#endif
Gpio_t Led2;
Gpio_t Led3;
Gpio_t Led4;
/*
* MCU objects
*/
Adc_t Adc;
I2c_t I2c;
Uart_t Uart1;
/*!
* Initializes the unused GPIO to a know status
*/
static void BoardUnusedIoInit( void );
/*!
* System Clock Configuration
*/
static void SystemClockConfig( void );
/*!
* Used to measure and calibrate the system wake-up time from STOP mode
*/
static void CalibrateSystemWakeupTime( void );
/*!
* System Clock Re-Configuration when waking up from STOP mode
*/
static void SystemClockReConfig( void );
/*!
* Timer used at first boot to calibrate the SystemWakeupTime
*/
static TimerEvent_t CalibrateSystemWakeupTimeTimer;
/*!
* Flag to indicate if the MCU is Initialized
*/
static bool McuInitialized = false;
/*!
* UART2 FIFO buffers size
*/
#define UART1_FIFO_TX_SIZE 1024
#define UART1_FIFO_RX_SIZE 1024
uint8_t Uart1TxBuffer[UART1_FIFO_TX_SIZE];
uint8_t Uart1RxBuffer[UART1_FIFO_RX_SIZE];
/*!
* Flag to indicate if the SystemWakeupTime is Calibrated
*/
static volatile bool SystemWakeupTimeCalibrated = false;
/*!
* Callback indicating the end of the system wake-up time calibration
*/
static void OnCalibrateSystemWakeupTimeTimerEvent( void* context )
{
RtcSetMcuWakeUpTime( );
SystemWakeupTimeCalibrated = true;
}
void BoardCriticalSectionBegin( uint32_t *mask )
{
*mask = __get_PRIMASK( );
__disable_irq( );
}
void BoardCriticalSectionEnd( uint32_t *mask )
{
__set_PRIMASK( *mask );
}
void BoardInitPeriph( void )
{
}
void BoardInitMcu( void )
{
if( McuInitialized == false )
{
HAL_Init( );
// LEDs
#if ( USE_POTENTIOMETER == 0 )
GpioInit( &Led1, LED_1, PIN_OUTPUT, PIN_PUSH_PULL, PIN_NO_PULL, 1 );
#endif
GpioInit( &Led2, LED_2, PIN_OUTPUT, PIN_PUSH_PULL, PIN_NO_PULL, 1 );
GpioInit( &Led3, LED_3, PIN_OUTPUT, PIN_PUSH_PULL, PIN_NO_PULL, 1 );
GpioInit( &Led4, LED_4, PIN_OUTPUT, PIN_PUSH_PULL, PIN_NO_PULL, 1 );
SystemClockConfig( );
FifoInit( &Uart1.FifoTx, Uart1TxBuffer, UART1_FIFO_TX_SIZE );
FifoInit( &Uart1.FifoRx, Uart1RxBuffer, UART1_FIFO_RX_SIZE );
// Configure your terminal for 8 Bits data (7 data bit + 1 parity bit), no parity and no flow ctrl
UartInit( &Uart1, UART_1, UART_TX, UART_RX );
UartConfig( &Uart1, RX_TX, 921600, UART_8_BIT, UART_1_STOP_BIT, NO_PARITY, NO_FLOW_CTRL );
RtcInit( );
// Switch LED 1, 2, 3, 4 OFF
#if ( USE_POTENTIOMETER == 0 )
GpioWrite( &Led1, 0 );
#endif
GpioWrite( &Led2, 0 );
GpioWrite( &Led3, 0 );
GpioWrite( &Led4, 0 );
BoardUnusedIoInit( );
if( GetBoardPowerSource( ) == BATTERY_POWER )
{
// Disables OFF mode - Enables lowest power mode (STOP)
LpmSetOffMode( LPM_APPLI_ID, LPM_DISABLE );
}
}
else
{
SystemClockReConfig( );
}
AdcInit( &Adc, POTI );
SpiInit( &SX1272.Spi, SPI_1, RADIO_MOSI, RADIO_MISO, RADIO_SCLK, NC );
SX1272IoInit( );
if( McuInitialized == false )
{
McuInitialized = true;
SX1272IoDbgInit( );
SX1272IoTcxoInit( );
if( GetBoardPowerSource( ) == BATTERY_POWER )
{
CalibrateSystemWakeupTime( );
}
}
}
void BoardResetMcu( void )
{
CRITICAL_SECTION_BEGIN( );
//Restart system
NVIC_SystemReset( );
}
void BoardDeInitMcu( void )
{
Gpio_t ioPin;
AdcDeInit( &Adc );
SpiDeInit( &SX1272.Spi );
SX1272IoDeInit( );
GpioInit( &ioPin, OSC_HSE_IN, PIN_ANALOGIC, PIN_PUSH_PULL, PIN_NO_PULL, 1 );
GpioInit( &ioPin, OSC_HSE_OUT, PIN_ANALOGIC, PIN_PUSH_PULL, PIN_NO_PULL, 1 );
GpioInit( &ioPin, OSC_LSE_IN, PIN_INPUT, PIN_PUSH_PULL, PIN_PULL_DOWN, 1 );
GpioInit( &ioPin, OSC_LSE_OUT, PIN_INPUT, PIN_PUSH_PULL, PIN_PULL_DOWN, 1 );
}
uint32_t BoardGetRandomSeed( void )
{
return ( ( *( uint32_t* )ID1 ) ^ ( *( uint32_t* )ID2 ) ^ ( *( uint32_t* )ID3 ) );
}
void BoardGetUniqueId( uint8_t *id )
{
id[7] = ( ( *( uint32_t* )ID1 )+ ( *( uint32_t* )ID3 ) ) >> 24;
id[6] = ( ( *( uint32_t* )ID1 )+ ( *( uint32_t* )ID3 ) ) >> 16;
id[5] = ( ( *( uint32_t* )ID1 )+ ( *( uint32_t* )ID3 ) ) >> 8;
id[4] = ( ( *( uint32_t* )ID1 )+ ( *( uint32_t* )ID3 ) );
id[3] = ( ( *( uint32_t* )ID2 ) ) >> 24;
id[2] = ( ( *( uint32_t* )ID2 ) ) >> 16;
id[1] = ( ( *( uint32_t* )ID2 ) ) >> 8;
id[0] = ( ( *( uint32_t* )ID2 ) );
}
/*!
* Potentiometer max and min levels definition
*/
#define POTI_MAX_LEVEL 900
#define POTI_MIN_LEVEL 10
uint8_t BoardGetPotiLevel( void )
{
uint8_t potiLevel = 0;
uint16_t vpoti = 0;
// Read the current potentiometer setting
vpoti = AdcReadChannel( &Adc , ADC_CHANNEL_3 );
// check the limits
if( vpoti >= POTI_MAX_LEVEL )
{
potiLevel = 100;
}
else if( vpoti <= POTI_MIN_LEVEL )
{
potiLevel = 0;
}
else
{
// if the value is in the area, calculate the percentage value
potiLevel = ( ( vpoti - POTI_MIN_LEVEL ) * 100 ) / POTI_MAX_LEVEL;
}
return potiLevel;
}
/*!
* Factory power supply
*/
#define FACTORY_POWER_SUPPLY 3300 // mV
/*!
* VREF calibration value
*/
#define VREFINT_CAL ( *( uint16_t* )0x1FF800F8U )
/*!
* ADC maximum value
*/
#define ADC_MAX_VALUE 4095
/*!
* VREF bandgap value
*/
#define ADC_VREF_BANDGAP 1224 // mV
/*!
* Battery thresholds
*/
#define BATTERY_MAX_LEVEL 3000 // mV
#define BATTERY_MIN_LEVEL 2400 // mV
#define BATTERY_SHUTDOWN_LEVEL 2300 // mV
static uint16_t BatteryVoltage = BATTERY_MAX_LEVEL;
uint16_t BoardBatteryMeasureVoltage( void )
{
uint16_t vref = 0;
uint32_t batteryVoltage = 0;
// Read the current Voltage
vref = AdcReadChannel( &Adc , ADC_CHANNEL_17 );
// We don't use the VREF from calibValues here.
// calculate the Voltage in millivolt
batteryVoltage = ( uint32_t )ADC_VREF_BANDGAP * ( uint32_t )ADC_MAX_VALUE;
batteryVoltage = batteryVoltage / ( uint32_t )vref;
return batteryVoltage;
}
uint32_t BoardGetBatteryVoltage( void )
{
return BatteryVoltage;
}
uint8_t BoardGetBatteryLevel( void )
{
uint8_t batteryLevel = 0;
BatteryVoltage = BoardBatteryMeasureVoltage( );
if( GetBoardPowerSource( ) == USB_POWER )
{
batteryLevel = 0;
}
else
{
if( BatteryVoltage >= BATTERY_MAX_LEVEL )
{
batteryLevel = 254;
}
else if( ( BatteryVoltage > BATTERY_MIN_LEVEL ) && ( BatteryVoltage < BATTERY_MAX_LEVEL ) )
{
batteryLevel = ( ( 253 * ( BatteryVoltage - BATTERY_MIN_LEVEL ) ) / ( BATTERY_MAX_LEVEL - BATTERY_MIN_LEVEL ) ) + 1;
}
else if( ( BatteryVoltage > BATTERY_SHUTDOWN_LEVEL ) && ( BatteryVoltage <= BATTERY_MIN_LEVEL ) )
{
batteryLevel = 1;
}
else //if( BatteryVoltage <= BATTERY_SHUTDOWN_LEVEL )
{
batteryLevel = 255;
}
}
return batteryLevel;
}
static void BoardUnusedIoInit( void )
{
Gpio_t ioPin;
if( GetBoardPowerSource( ) == BATTERY_POWER )
{
GpioInit( &ioPin, USB_DM, PIN_ANALOGIC, PIN_PUSH_PULL, PIN_NO_PULL, 0 );
GpioInit( &ioPin, USB_DP, PIN_ANALOGIC, PIN_PUSH_PULL, PIN_NO_PULL, 0 );
}
#if defined( USE_DEBUGGER )
HAL_DBGMCU_EnableDBGSleepMode( );
HAL_DBGMCU_EnableDBGStopMode( );
HAL_DBGMCU_EnableDBGStandbyMode( );
#else
HAL_DBGMCU_DisableDBGSleepMode( );
HAL_DBGMCU_DisableDBGStopMode( );
HAL_DBGMCU_DisableDBGStandbyMode( );
GpioInit( &ioPin, JTAG_TMS, PIN_ANALOGIC, PIN_PUSH_PULL, PIN_NO_PULL, 0 );
GpioInit( &ioPin, JTAG_TCK, PIN_ANALOGIC, PIN_PUSH_PULL, PIN_NO_PULL, 0 );
GpioInit( &ioPin, JTAG_TDI, PIN_ANALOGIC, PIN_PUSH_PULL, PIN_NO_PULL, 0 );
GpioInit( &ioPin, JTAG_TDO, PIN_ANALOGIC, PIN_PUSH_PULL, PIN_NO_PULL, 0 );
GpioInit( &ioPin, JTAG_NRST, PIN_ANALOGIC, PIN_PUSH_PULL, PIN_NO_PULL, 0 );
#endif
}
void SystemClockConfig( void )
{
RCC_OscInitTypeDef RCC_OscInitStruct;
RCC_ClkInitTypeDef RCC_ClkInitStruct;
RCC_PeriphCLKInitTypeDef PeriphClkInit;
__HAL_RCC_PWR_CLK_ENABLE( );
__HAL_PWR_VOLTAGESCALING_CONFIG( PWR_REGULATOR_VOLTAGE_SCALE1 );
RCC_OscInitStruct.OscillatorType = RCC_OSCILLATORTYPE_HSE | RCC_OSCILLATORTYPE_LSE;
RCC_OscInitStruct.HSEState = RCC_HSE_ON;
RCC_OscInitStruct.LSEState = RCC_LSE_ON;
RCC_OscInitStruct.PLL.PLLState = RCC_PLL_ON;
RCC_OscInitStruct.PLL.PLLSource = RCC_PLLSOURCE_HSE;
RCC_OscInitStruct.PLL.PLLMUL = RCC_PLL_MUL6;
RCC_OscInitStruct.PLL.PLLDIV = RCC_PLL_DIV3;
if( HAL_RCC_OscConfig( &RCC_OscInitStruct ) != HAL_OK )
{
assert_param( FAIL );
}
RCC_ClkInitStruct.ClockType = RCC_CLOCKTYPE_HCLK | RCC_CLOCKTYPE_SYSCLK |
RCC_CLOCKTYPE_PCLK1 | RCC_CLOCKTYPE_PCLK2;
RCC_ClkInitStruct.SYSCLKSource = RCC_SYSCLKSOURCE_PLLCLK;
RCC_ClkInitStruct.AHBCLKDivider = RCC_SYSCLK_DIV1;
RCC_ClkInitStruct.APB1CLKDivider = RCC_HCLK_DIV1;
RCC_ClkInitStruct.APB2CLKDivider = RCC_HCLK_DIV1;
if( HAL_RCC_ClockConfig( &RCC_ClkInitStruct, FLASH_LATENCY_1 ) != HAL_OK )
{
assert_param( FAIL );
}
PeriphClkInit.PeriphClockSelection = RCC_PERIPHCLK_RTC;
PeriphClkInit.RTCClockSelection = RCC_RTCCLKSOURCE_LSE;
if( HAL_RCCEx_PeriphCLKConfig( &PeriphClkInit ) != HAL_OK )
{
assert_param( FAIL );
}
HAL_SYSTICK_Config( HAL_RCC_GetHCLKFreq( ) / 1000 );
HAL_SYSTICK_CLKSourceConfig( SYSTICK_CLKSOURCE_HCLK );
// SysTick_IRQn interrupt configuration
HAL_NVIC_SetPriority( SysTick_IRQn, 0, 0 );
}
void CalibrateSystemWakeupTime( void )
{
if( SystemWakeupTimeCalibrated == false )
{
TimerInit( &CalibrateSystemWakeupTimeTimer, OnCalibrateSystemWakeupTimeTimerEvent );
TimerSetValue( &CalibrateSystemWakeupTimeTimer, 1000 );
TimerStart( &CalibrateSystemWakeupTimeTimer );
while( SystemWakeupTimeCalibrated == false )
{
}
}
}
void SystemClockReConfig( void )
{
__HAL_RCC_PWR_CLK_ENABLE( );
__HAL_PWR_VOLTAGESCALING_CONFIG( PWR_REGULATOR_VOLTAGE_SCALE1 );
// Enable HSE
__HAL_RCC_HSE_CONFIG( RCC_HSE_ON );
// Wait till HSE is ready
while( __HAL_RCC_GET_FLAG( RCC_FLAG_HSERDY ) == RESET )
{
}
// Enable PLL
__HAL_RCC_PLL_ENABLE( );
// Wait till PLL is ready
while( __HAL_RCC_GET_FLAG( RCC_FLAG_PLLRDY ) == RESET )
{
}
// Select PLL as system clock source
__HAL_RCC_SYSCLK_CONFIG ( RCC_SYSCLKSOURCE_PLLCLK );
// Wait till PLL is used as system clock source
while( __HAL_RCC_GET_SYSCLK_SOURCE( ) != RCC_SYSCLKSOURCE_STATUS_PLLCLK )
{
}
}
void SysTick_Handler( void )
{
HAL_IncTick( );
HAL_SYSTICK_IRQHandler( );
}
uint8_t GetBoardPowerSource( void )
{
return USB_POWER;
}
/**
* \brief Enters Low Power Stop Mode
*
* \note ARM exists the function when waking up
*/
void LpmEnterStopMode( void)
{
CRITICAL_SECTION_BEGIN( );
BoardDeInitMcu( );
// Disable the Power Voltage Detector
HAL_PWR_DisablePVD( );
// Clear wake up flag
SET_BIT( PWR->CR, PWR_CR_CWUF );
// Enable Ultra low power mode
HAL_PWREx_EnableUltraLowPower( );
// Enable the fast wake up from Ultra low power mode
HAL_PWREx_EnableFastWakeUp( );
CRITICAL_SECTION_END( );
// Enter Stop Mode
HAL_PWR_EnterSTOPMode( PWR_LOWPOWERREGULATOR_ON, PWR_STOPENTRY_WFI );
}
/*!
* \brief Exists Low Power Stop Mode
*/
void LpmExitStopMode( void )
{
// Disable IRQ while the MCU is not running on HSI
CRITICAL_SECTION_BEGIN( );
// Initilizes the peripherals
BoardInitMcu( );
CRITICAL_SECTION_END( );
}
/*!
* \brief Enters Low Power Sleep Mode
*
* \note ARM exits the function when waking up
*/
void LpmEnterSleepMode( void)
{
HAL_PWR_EnterSLEEPMode(PWR_MAINREGULATOR_ON, PWR_SLEEPENTRY_WFI);
}
void BoardLowPowerHandler( void )
{
__disable_irq( );
/*!
* If an interrupt has occurred after __disable_irq( ), it is kept pending
* and cortex will not enter low power anyway
*/
LpmEnterLowPower( );
__enable_irq( );
}
#if !defined ( __CC_ARM )
/*
* Function to be used by stdout for printf etc
*/
int _write( int fd, const void *buf, size_t count )
{
while( UartPutBuffer( &Uart1, ( uint8_t* )buf, ( uint16_t )count ) != 0 ){ };
return count;
}
/*
* Function to be used by stdin for scanf etc
*/
int _read( int fd, const void *buf, size_t count )
{
size_t bytesRead = 0;
while( UartGetBuffer( &Uart1, ( uint8_t* )buf, count, ( uint16_t* )&bytesRead ) != 0 ){ };
// Echo back the character
while( UartPutBuffer( &Uart1, ( uint8_t* )buf, ( uint16_t )bytesRead ) != 0 ){ };
return bytesRead;
}
#else
#include <stdio.h>
// Keil compiler
int fputc( int c, FILE *stream )
{
while( UartPutChar( &Uart1, ( uint8_t )c ) != 0 );
return c;
}
int fgetc( FILE *stream )
{
uint8_t c = 0;
while( UartGetChar( &Uart1, &c ) != 0 );
// Echo back the character
while( UartPutChar( &Uart1, c ) != 0 );
return ( int )c;
}
#endif
#ifdef USE_FULL_ASSERT
#include <stdio.h>
/*
* Function Name : assert_failed
* Description : Reports the name of the source file and the source line number
* where the assert_param error has occurred.
* Input : - file: pointer to the source file name
* - line: assert_param error line source number
* Output : None
* Return : None
*/
void assert_failed( uint8_t* file, uint32_t line )
{
/* User can add his own implementation to report the file name and line number,
ex: printf("Wrong parameters value: file %s on line %lu\n", file, line) */
printf( "Wrong parameters value: file %s on line %lu\n", ( const char* )file, line );
/* Infinite loop */
while( 1 )
{
}
}
#endif
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